KR20010005538A - Waste treatment apparatus and method - Google Patents

Abstract

After crushing the containerized medical waste 12, the crushed material is passed through a direct steam jet injection step and a dehydration step using a screw conveyor 34 to bring the crushed material into contact with a hot surface to evaporate moisture. Treatment is by passing steam through a low pressure chamber.

Description

Waste treatment equipment and treatment method {WASTE TREATMENT APPARATUS AND METHOD}

Waste treatment devices of the type to which the present invention is concerned are typically installed in commercial medical waste disposal plants or in the field of hospitals or other medical facilities. All infectious waste produced during plant operation is being treated by a waste disposal system. The device disposes of the treated product, compacts it, safely stores it in a conventional waste container, puts it in a conventional waste transport truck or a simple container, and transports it to a landfill or similar facility for disposal.

An important aspect of infectious waste disposal is that the final waste that is disposed of must not contain pathogenic microorganisms. In addition, it is extremely desirable to dispose of the waste in such a state that individual objects such as disposable syringes, bandages and body fluid reservoirs cannot be identified, and in some cases are regulated by law.

In the past, medical waste was conventionally incinerated. However, environmental regulations severely limit the incineration of waste. Other treatments are used, including steam autoclave treatment and chemical treatment. Some of these methods have little effect on the destruction of pathogenic microorganisms. Some other effective methods require equipment that is expensive to install, expensive to operate and difficult to operate. Another problem with operating medical waste disposal systems is that sometimes odors and harmful gases, liquids and solid particles are released into the sewage system or into the atmosphere.

Many of the problems encountered in the treatment of medical waste in the past are addressed in US Pat. No. 5,570,845, filed Nov. 5, 1996 to Sterile Technology Industries. The patent discloses a method and apparatus for transferring containerized waste to a shredder through a conveyor under negative pressure.

The sanitizing solution is added at several points in the shredder section of the device. The crushed in the crusher is compressed to recycle the separated liquid component. Steam is introduced to move the compacted solid through a conveyor that maintains the temperature of the waste to just below 212 ° F. At all points in the system, the pressure is maintained at or below atmospheric pressure to prevent contaminants from being released into the atmosphere. By using the sanitizing solution and steam together, it is possible to almost eliminate live bacteria while using negative pressure to avoid accidental release of contaminants. The entirety disclosed in U.S. Patent No. 5,570,845 is incorporated herein by reference.

The present invention is an improvement on the apparatus and method described in US Pat. No. 5,570,845. The drawback of the device according to the patent is that even though it contains little pathogenic probiotics, the discharged waste contains a considerable amount of water, most of which comes from the steam used in the treatment. Therefore, the advantage of adding steam directly to the waste has the disadvantage that it adds weight to the treated waste, resulting in increased residual waste transportation costs.

The present invention relates to a waste treatment apparatus and a treatment method, and more particularly, to a treatment apparatus and a treatment method of regulated medical waste such as hospital waste.

1 is a schematic view of a preferred waste treatment apparatus according to the present invention.

[Mode for Carrying Out the Invention]

The complete treatment device embodying the present invention consists of two main parts, the shredding device 2 and the heat treatment device 4, in which the waste shredded into these are slowly transported by the conveyor and directly steam injected and dewatered. .

In this embodiment, the shredding device 2 in the processing device shown in the drawing includes a belt conveyor 6 inclined in the housing 8. This conveyor typically receives through intake opening 10 waste, such as packages, boxes or sharp containers, which are regulated medical waste. The package 12, which is waste, is shown above the conveyor. Other types of conveyors can also be used to transport waste into the device. For example, cart elevators, dumpers, combinations of carat elevators and dumpers or other suitable conveyors may be used in place of belt conveyors.

The hopper 14 below the top of the conveyor feeds the packaged waste to a shredding mechanism 16 with conventional mutually rotating cutters. This shredding mechanism can be in various shapes appropriately selected depending on the waste to be treated. For example, it may be a two-axis or four-axis crusher, or may be a plurality of biaxial crushers or other various crusher shapes.

The reciprocating ram mechanism above the hinge 20 has a pusher plate 22, which is adapted to force gravity to move the waste into the fracturing mechanism by pressing downward against the waste in the hopper 14. Function to add. Other types of ram, such as piston ram, may be used.

The blower 24 blows air from the housing 8 through a high efficiency particulate air filter. By maintaining the flow of air flowing through the inlet 10 by the blower inwardly, particles are not discharged through the inlet. Preferably, the blower 24 constitutes an interlock (not shown) that prevents the inflow of waste raw materials when the air is not sucked in through the inlet.

The sanitary spray nozzle 27 intermittently introduces a sanitizing solution (preferably sodium hypochlorite) into the housing 8 to grow the colony of microorganisms in the housing 8 and in the shredding device 2. To prevent.

The heat treatment apparatus 4 has an inclined length having an inlet 30 for receiving shredded waste from the shredding mechanism 16 at one end of the lower side and an outlet 32 for discharging the treated waste at one end of the upper side. It includes a long outer shell body (28).

The long sheath cylinder preferably has a cylindrical inner wall and a helical screw conveyor 34 extending through the inner wall and moving the crushed waste from the inlet 30 to the outlet 32. The spiral screw conveyor is preferably installed with a slight gap between the blade and the cylindrical inner wall of the shell cylinder in the shell cylinder, which rotates through the chain 37 by the drive of the motor 36. .

The steam supplied through the conduit 38 passes through a plurality of injection inlets 40 spaced apart from each other in the longitudinal direction at the intermediate position 42 between the inlet 30 and the outlet and the inlet 30. 28) Inject at a pressure of 15 psi or less. The steam injection inlet allows steam to directly contact the crushed waste in the direct steam injection inlet of the shell cylinder extending from the position adjacent the inlet 30 to the intermediate position 42.

The screw conveyor 34 agitates and shreds the crushed waste to increase contact between the steam and the waste. Mixing tabs (not shown) may be configured on the screw conveyor to allow steam to penetrate the waste well. The speed of the screw conveyor is adjusted so that the residence time of the waste in the steam jet inlet is about 30 minutes. A thermocouple 43 is installed at the bottom of the shell cylinder 28. The first thermocouple actuates a valve (not shown) to control the steam flow rate by means of which the temperature of the waste along the length of the steam injection inlet ranges from 205 ° F. to 212 ° F., preferably between 205 ° F. and 210 ° F. Keep it in range.

The steam jacket 44 surrounds the outer shell body 28 past the intermediate position 42. The steam jacket is preferably supplied with low pressure steam from the same source that supplies steam to the direct injection inlet. The temperature of the steam in this steam jacket is maintained at a temperature at which the inner wall surface of the outer shell body 28 is maintained at a temperature of 212 ° F or more, preferably in the range of 220 ° F to 235 ° F. Preferably steam is supplied at 235 ° F. to condense in the waste at temperatures ranging from 205 ° F. to 212 ° F. The steam temperature in the jacket is controlled by a second thermocouple 43 installed on the steam jacket or in the steam jacket to actuate a valve to control the steam flow rate.

By the action of the screw conveyor, the contact between the waste and the high temperature cylindrical inner wall of the shell cylinder 28 is good. Therefore, the steam jacket is subjected to the second stage treatment of converting the water in the waste into water vapor by contacting the hot surface with the waste. At this stage the waste is dehydrated and the weight is reduced

Water is discharged from the inside of the shell cylinder at a position between the steam jacket and the outlet by the blower 46 connected to the outlet 48 so that the moisture in the steam generated by the heat of the steam jacket cannot be circulated to the waste. Either the steam is released into the atmosphere or water is circulated to the steam source using a condenser 50 at the outlet of the blower 46. The condenser is particularly useful when the apparatus of the present invention is installed in a building. The discharge of the water is caused by the low pressure maintained by the blower 46 installed in the shell cylinder adjacent to the outlet 32. A flapper 52 with a counterweight 54 typically maintains the outlet in a closed state so that a low pressure chamber can be maintained at the top end of the conveyor. However, as the waste accumulates in the outlet, the flapper is opened by the weight of the waste so that the waste is discharged toward the compactor 56.

Heating the waste by the steam jacket causes the waste to begin dehydration and completes the dehydration by evacuating the steam from the low pressure chamber. Therefore, in the preferred embodiment of the present invention, the portion enclosed by the steam jacket and the low pressure chamber together constitute a dehydration step.

This waste treatment device does not rely on sterilization chemical treatment. Hygienic spray simply prevents the accumulation of colonies of microorganisms in the source and shredding mechanisms and introduces minimal amounts of water to the waste. Minimizing the introduction of water in the preliminary stage increases the efficiency of the dehydration stage, improving heat transfer during direct steam injection injection, killing pathogenic microorganisms and obtaining lightweight waste treatment. Direct injection of steam into the waste can completely destroy the live bacteria. Water introduced into the waste in the direct steam injection step is removed in the dehydration step of the unit.

Various changes can be made to the above apparatus. For example, the screw conveyor may be composed of two or more sections, each controlled separately. As long as there is no deviation from the scope of the present invention as defined in the following claims, other various changes can be made to the apparatus, and various modifications can also be made to the method of use.

Therefore, the main object of the present invention is to improve the infectious waste, which is capable of completely extinguishing pathogenic microorganisms and treating wastes indistinguishably, and improving the conventional system by producing waste water with low moisture content. In providing a processing system.

A preferred waste treatment apparatus according to the present invention comprises an elongated envelope having an inlet for receiving shredded waste at one end and an outlet for discharging the treated waste at the other end. The crushed waste is conveyed from the inlet of the shell cylinder to the outlet port by a conveyor, preferably a rotary screw conveyor. A conduit is connected from the steam source to the interior of the shell cylinder so that steam is in direct contact with the waste in the first section of the shell cylinder extending from the position adjacent the inlet to the intermediate position between the inlet and the outlet. The waste in the second section of the shell cylinder along the length between the intermediate position and the outlet is dewatered by heating, preferably by a steam jacket enclosing the shell cylinder. In general, the same steam source is used to supply steam to the steam jacket, making direct contact with the waste.

In a preferred embodiment, the blower is connected to the inside of the shell cylinder at a position away from the first section. The blower sets the pressure in a part of the shell cylinder below atmospheric pressure to remove water and water vapor from the waste. Preferably, the blower is connected to the inside of the shell cylinder at a position between the steam jacket and the outlet so that the low pressure shell portion of the sub-atmospheric pressure becomes a third section acting as a low pressure chamber.

Shredding the waste by the apparatus and direct contacting the shredded waste with steam for at least 30 minutes at an elevated temperature of at least about 205 ° F. to 212 ° F., and thereafter at a temperature of not more than 212 ° F., preferably May implement a novel treatment method for an infectious waste comprising contacting the waste to a surface heated to a temperature in the range of 220 ° F. to 235 ° F. to dehydrate the waste.

In the dehydration step, it is desirable to remove the moisture by exposing the waste to sub-atmospheric pressure. The crushed waste is continuously transported by the rotating screw conveyor through the steam contacting step and the dehydration step, and the crushed waste is mixed in the screw conveyor to allow a large amount of steam to penetrate into the waste during the steam contacting step. This will increase the contact of the heated surface with the waste.

In the shredding step, it is desirable to spray the sanitizing solution periodically into the shredding device so that colony of microorganisms is not produced. The waste treatment apparatus and method of the present invention effectively and efficiently kill pathogenic microorganisms by using mechanical crushing, direct steam injection, and dehydration, and discharge the relatively light treated waste with much lower moisture content. This is much easier.

Various other objects, technical configurations and advantages of the present invention will be described in detail below with reference to the drawings.

Claims (14)

(A) an elongated outer shell body 28 having an inlet 30 for receiving shredded waste 12 at one end and an outlet 32 for discharging the treated waste at the opposite end thereof; (B) a conveyor 34 for transferring the crushed waste from the inlet 30 to the outlet 32 of the elongated shell cylinder 28; (C) the steam source; (D) from the steam source to the interior of the shell cylinder 28 and extending from the position adjacent the inlet 30 toward the intermediate position 42 between the inlet 30 and the outlet 32; A conduit for direct steam contact with the waste in section 1, (E) a waste comprising a steam jacket 44 for heating the waste in the second section, surrounding a second section of the shell cylinder 28 along a portion of the length between the intermediate position 42 and the outlet 32; Processing unit. The method of claim 1, wherein the water is removed from the waste by forming a low pressure chamber lower than atmospheric pressure in a part of the shell cylinder 28 connected to the inside of the shell cylinder 28 at a position away from the first section. Waste treatment apparatus comprising a blower (46). 2. The jacketed body (28) according to claim 1, wherein the second section of the jacketed body (28) surrounded by the steam jacket (44) is separated from the outlet (32), and the jacketed body (28) at a position between the steam jacket (44) and the outlet (32). And a blower (46) connected to the inside of the shell to remove moisture from the waste by forming a third section having a low pressure lower than atmospheric pressure in the shell cylinder (28). A waste disposal apparatus according to claim 1, wherein the conveyor comprises a screw conveyor (34) extending longitudinally through the inside of the elongate shell cylinder (28). A waste disposal apparatus according to claim 1, wherein the conveyor includes a screw conveyor (34) extending longitudinally through the first and second sections of the cylinder (28). The waste disposal apparatus of claim 1, wherein the steam jacket is connected to a steam source to receive steam from the steam source. The shredder (16) according to claim 1, wherein the shredder (16) is arranged to supply the shredded waste to the inlet (30) of the elongated shell cylinder (28), the feed conveyor (6) for supplying the waste to the shredder (16), A housing (8) surrounding a passage extending from the feed conveyor (6) to the shredder (16) surrounding at least a portion of the feed conveyor (6) and connected to the housing (8) to the housing (8); Waste treatment apparatus comprising a blower (24) for maintaining the air flow for. (A) means for forming an enclosed passageway for the transport of shredded waste, the means having an inlet 30 for receiving the shredded waste at one end and an outlet 32 for discharging the treated waste at the other end thereof; (B) conveyor means 34 for conveying shredded waste from the inlet 30 to the outlet 32 via an enclosed passageway, (C) Means for direct steam contacting the waste in the first section of the enclosed passage extending from the position adjacent the inlet 30 toward the intermediate position 42 between the inlet 30 and the outlet 32. , 40), And (d) means (44) for heating waste in a second section of the enclosed passage downstream from the first section in the direction of movement of the crushed waste. (A) crushing the waste, (B) contacting the waste directly with steam for an interval of at least 30 minutes at a temperature which maintains the waste at an elevated temperature of at least about 205 ° F. and not more than 212 ° F .; (C) thereafter, contacting the waste with a surface heated to a temperature of at least 212 ° F. to dehydrate the waste. 10. The method of claim 9 wherein the waste is exposed to sub-atmospheric pressure in the dehydration step. 10. The method according to claim 9, wherein the crushed waste is continuously transferred by a rotary screw conveyor through a steam connection step to perform a contacting step, and the dewatered water is passed through a dehydration step, and the crushed waste is removed by a screw conveyor. By mixing to increase the penetration of steam into the waste stream in the steam contacting step, as well as to increase the contact between the heated surface and the waste in the dewatering step. The method of claim 9, wherein the waste is contacted in a dehydration step maintained at a temperature in the range of about 220 ° F. to 235 ° F. 10. 10. The method of claim 9, wherein the waste is sequentially transported through a steam contacting step of performing a contacting step and a sequential dehydration step of contacting the heated surface with a pressure below atmospheric pressure. 10. The treatment method according to claim 9, wherein the shredding step is carried out in a shredding device, and the sanitizing solution is periodically sprayed into the shredding device to prevent the generation of colonies of microorganisms in the shredding device.